Jan-Arne Björkman

Ticagrelor Inhibits Adenosine Uptake In Vitro and Enhances Adenosine-Mediated Hyperemia Responses in a Canine Model

Aims: A routine secondary pharmacology screen indicated that reversibly binding oral P2Y12 receptor antagonist ticagrelor could inhibit adenosine uptake in human erythrocytes, suggesting that ticagrelor may potentiate adenosine-mediated responses in vivo. The aim of this study was to further characterize the adenosine uptake inhibition in vitro and study possible physiological consequences of adenosine uptake inhibition by ticagrelor in an anesthetized dog model of coronary blood flow compared to dipyridamole. Methods and Results: We measured [2-3H]adenosine uptake in purified human erythrocytes and several cell lines in the presence of ticagrelor or the known uptake inhibitor dipyridamole as a comparator. Using an open-chest dog model (beagles), we measured the left anterior descending (LAD) coronary artery blood flow during reactive hyperemia after 1 minute occlusion or intracoronary infusion of adenosine before and after administration of vehicle, ticagrelor, or dipyridamole (each n = 8). Ticagrelor concentration-dependently inhibited adenosine uptake in human erythrocytes and in cell lines of rat, canine, or human origin. In the dog model, ticagrelor and dipyridamole dose-dependently augmented reactive hyperemia after LAD occlusion, as assessed by percentage repayment of flow debt relative to control (both Ps < .05). Ticagrelor and dipyridamole also dose-dependently augmented intracoronary adenosine-induced increases in LAD blood flow relative to control (both Ps < .05). Conclusion: Ticagrelor inhibits adenosine uptake in vitro and subsequently augments cardiac blood flow in a canine model of reactive hypoxia- or adenosine-induced blood flow increases. These findings suggest that ticagrelor may have additional benefits in patients with acute coronary syndrome beyond inhibition of platelet aggregation.

The role of sympathetic activity in atherogenesis: Effects of β-blockade

Abstract Clinical and experimental evidence points to potential antiatherosclerotic effects of certain β-adrenoreceptor antagonists. Long-term treatment with metoprolol resulted in significant reductions of total and cardiovascular mortality or morbidity due to decreased incidence of coronary and cerebrovascular complications both in a primary prevention trial in hypertensive patients and in a secondary prevention trial in patients surviving myocardial infarction. The observations suggest that a retardation of atherosclerosis development might have contributed to the reduced incidence of cardiovascular complications. An antiatherosclerotic effect of β-blockers has been directly demonstrated in animal studies. In cholesterol-fed rabbits, metoprolol significantly reduced the development of atherosclerotic plaques in the aortic intima in the absence of any changes in blood lipids. Similar findings were reported for propranolol, which prevented psychosocial stress-induced atherosclerosis of the coronary artery in monkeys. Furthermore, β-blockers have been shown to prevent stress-induced endothelial injury and platelet accumulation to intima at atherosclerotic predilection sites in animal models. These antiatherogenic effects may be due to biochemical and hemodynamic factors. Two biochemical effects of β-blockade may lead to reduced cholesterol accumulation in arterial intima at unchanged serum cholesterol levels. One is a β-blocker-induced increase of prostacyclin biosynthesis, and the other a metabolic change of low-density lipoprotein, reducing its potential for deposition in the arterial wall. The antiatherogenic effect of these factors may be reinforced by β-blocker-induced hemodynamic changes leading to reductions of arterial flow aberrations and pressure-related wall stress.

Comparison of ticagrelor and thienopyridine P2Y12 binding characteristics and antithrombotic and bleeding effects in rat and dog models of thrombosis/hemostasis

Ticagrelor (AZD6140), the first reversibly binding oral P2Y(12) receptor antagonist, blocks adenosine diphosphate (ADP)-induced platelet aggregation via a mode of action distinct from that of thienopyridine antiplatelet agents. The latter must be metabolically activated and binds irreversibly to P2Y(12) for the life of the platelet, precluding restoration of hemostatic function without the generation of new platelets. In in vitro studies comparing binding characteristics of ticagrelor and compound 105, a chemical compound indistinguishable from the active metabolite of prasugrel, ticagrelor exhibited 1) an approximately 100-fold higher affinity for P2Y(12) and rapid achievement of equilibrium (vs no equilibrium reached with compound 105) as assessed by radioligand displacement in a receptor filtration binding assay, 2) 48-fold greater potency in a functional receptor assay using recombinant human P2Y(12), and 3) 63-fold greater potency in inhibiting ADP-induced aggregation in washed human platelets. In rat and dog models of thrombosis/hemostasis, there was greater separation between doses that provided antithrombotic effect and those that increased bleeding for ticagrelor compared with clopidogrel and compound 072, a chemical compound indistinguishable from the prasugrel parent compound. The ratio of dose resulting in 3-fold increase in bleeding time to dose resulting in 50% restoration of blood flow in rats was 9.7 for ticagrelor compared with 2.0 for clopidogrel and 1.4 for compound 072. Similar results were observed in dogs. Our findings suggest that reversibility of P2Y(12) binding with ticagrelor may account for the greater separation between antithrombotic effects and increased bleeding compared with the irreversible binding of clopidogrel and prasugrel.

Cardiac Sympathetic Nerve Stimulation Triggers Coronary t-PA Release

Objective—This study was undertaken to determine whether stimulation of sympathetic cardiac nerves induces release of the thrombolytic enzyme tissue-type plasminogen activator (t-PA) in the coronary vascular bed. Methods and Results—Anesthetized pigs were studied in an open chest model. Bilateral vagotomy was performed, and sympathetic cardiac nerves were activated by electrical stimulation (1 and 8 Hz). To evaluate possible mediating effects of increased heart rate and enhanced local blood flow, tachycardia was induced by pacing and hyperemia by local infusion of sodium nitroprusside and clevedipine. Furthermore, to study the effects of &agr;- and &bgr;-adrenergic receptor stimulation, phenylephrine and isoprenaline were infused locally. In response to low- and high-frequency sympathetic stimulation, mean coronary net release of total t-PA increased approximately 6- and 25-fold, respectively. Active t-PA showed a similar response pattern. Neither tachycardia nor coronary hyperemia stimulated t-PA release. In contrast, &bgr;-adrenergic stimulation by isoprenaline induced an approximately 6-fold increase in coronary t-PA release, whereas no significant change in release rates occurred in response to &agr;-adrenergic stimulation by phenylephrine. Conclusions—Stimulation of cardiac sympathetic nerves induces a marked coronary release of t-PA, and part of this response may be mediated through stimulation of &bgr;-adrenergic receptors.

Derivation of haemodynamic information from ultrasonic recordings of aortic diameter changes

An ultrasound phase-locked echo-tracking system was used for noninvasive measurements of diameter changes in the upper abdominal aorta of the anaesthetised cat. Comparisons were made between the noninvasively recorded diameter changes and central haemodynamic variables measured with inserted catheters and transducers. It was found that noninvasive observations of aortic diameter changes give reliable information on the direction and relative magnitude of the blood pressure change both in systole and in diastole. Indications of the direction of change of stroke volume, cardiac output, and aortic flow acceleration (a measure of cardiac inotropy) could also be gained. The information, taken together, comprises a pattern of response reflecting cardiovascular adjustments likely to have occurred. It is suggested that the technique is suitable for interpretation of (patho-) physiological changes in the foetus, as well as for determinations of great vessel compliance in man, i.e., in atherosclerosis research.

Lead Optimization of Ethyl 6-Aminonicotinate Acyl Sulfonamides as Antagonists of the P2Y12 Receptor. Separation of the Antithrombotic Effect and Bleeding for Candidate Drug AZD1283

Synthesis and structure-activity relationships of ethyl 6-aminonicotinate acyl sulfonamides, which are potent antagonists of the P2Y12 receptor, are presented. Shifting from 5-chlorothienyl to benzyl sulfonamides significantly increased the potency in the residual platelet count assay. Evaluation of PK parameters in vivo in dog for six compounds showed a 10-fold higher clearance for the azetidines than for the matched-pair piperidines. In a modified Folts model in dog, both piperidine 3 and azetidine 13 dose-dependently induced increases in blood flow and inhibition of ADP-induced platelet aggregation with antithrombotic ED50 values of 3.0 and 10 μg/kg/min, respectively. The doses that induced a larger than 3-fold increase in bleeding time were 33 and 100 μg/kg/min for 3 and 13, respectively. Thus, the therapeutic index (TI) was ≥ 10 for both compounds. On the basis of these data, compound 3 was progressed into human clinical trials as candidate drug AZD1283.

Usefulness of a nanoparticle formulation to investigate some hemodynamic parameters of a poorly soluble compound

Drug solubility is an important issue when progressing investigational compounds into clinical candidates. The present paper describes the development and characterization of a nanosuspension that was formulated to overcome problems with poor water solubility and possible adverse events caused by cosolvent mixtures, using ticagrelor as a model compound. A homogeneous nanosuspension of ticagrelor was formed using a wet milling approach, which yielded particle sizes around 230 nm. The nanosuspensions were chemically stable for at least 10 months at both room temperature and when refrigerated, and physically (i.e., particle size) stable for at least 10 months under refrigeration, and approximately 3 years at room temperature and when frozen. One rat model and two dog models were used to assess the pharmacokinetics and hemodynamic-related effects following intravenous administration of nanoparticles. There were no biologically consistent or dose-dependent effects of the nanoparticles on the hemodynamic parameters tested, that is, heart rate, mean aortic pressure, cardiac output, left femoral artery blood flow, or cardiac inotropy (measured as max dP/dt). In conclusion, a stable ticagrelor nanosuspension formulation was developed, suitable for intravenous administration. At the doses evaluated, this formulation was without hemodynamic effects in three sensitive preclinical models.

Ischemic and nonischemic tissue concentrations of felodipine after coronary venous retroinfusion during myocardial ischemia and reperfusion: an experimental study in pigs.

Tissue and plasma concentrations of felodipine, a dihydropyridine (DHP) calcium antagonist, retroinfused through the coronary venous system were studied in 27 pigs. The animals underwent 45-min myocardial ischemia followed by 4-h reperfusion. Felodipine (7 nmol/kg body weight) was administered in the coronary vein for 30 min, 5 min before reperfusion. Concentrations of felodipine in the ischemic and nonischemic myocardium and in plasma were determined by gas chromatography. In the ischemic area, felodipine concentration at start of reperfusion was 304 +/- 285, 171 +/- 160, and 52 +/- 47 nmol/kg (mean +/- SD) in the subepicardial, midmyocardial, and subendocardial layer, respectively. Corresponding concentrations in the nonischemic area were 15 +/- 13, 17 +/- 14, and 16 +/- 15 nmol/kg (p < 0.05 vs. ischemic area). Subepicardial concentration was highest at start of reperfusion, whereas concentrations in other layers peaked at the end of retroinfusion. The transmural concentration gradient of felodipine in the ischemic area decreased progressively during the reperfusion period. The nonischemic tissue concentration increased slightly during the reperfusion period. The plasma concentration was very low throughout the study (peak = 3.2 +/- 1.4 nM at 30 min). Coronary venous retroinfusion of felodipine resulted in profound accumulation of the drug, specifically in ischemic myocardium. The plasma concentration was low and did not affect systemic hemodynamics. Coronary venous retroinfusion is considered an advantageous technique for selective drug delivery.

Cardiac Antiischemic Effect of Metoprolol: Role of β-Blockade within the Ischemic Region

Summary: The distribution of metoprolol and atenolol into ischemic and nonischemic myocardium was studied in anesthetized dogs, pigs, and cats. The &bgr;‐blockers were administered intravenously after coronary artery occlusion. Metoprolol was found to be significantly more efficiently distributed to the ischemic myocardium than atenolol in all three species. To investigate the functional implications of this difference in tissue distribution, the antiischemic effects of the two &bgr;‐blockers were studied in the 2‐h period following coronary artery occlusion in anesthetized cats, in which heart rate was kept at a constant level. In this model, metoprolol (0.3 mg • kg−1 + 0.15 mg • kg−1 • h−1) was found to attenuate or delay the developing ischemic process. This is shown by its significant reduction of (a) the decline of CK activity in ischemic myocardium, (b) the ST elevation in a precordial ECG lead, and (c) the decrease of arterial pressure and cardiac output. In contrast to metoprolol, atenolol (0.3 mg • kg−1 + 0.15 mg • kg−1 • h−1) caused no significant antiischemic effect in this cat model. The difference in the effectiveness of the two drugs can most probably be explained by their differential distribution in the ischemic heart. Furthermore, the anti‐ischemic effect of metoprolol shows that the presence of a &bgr;‐blocker in ischemic left ventricular myocardium can favorably affect the early phase of developing infarction.

Influence of endogenous neuropeptide Y (NPY) on the sympathetic-parasympathetic interaction in the canine heart.

The purpose of this study was to examine the sympathetic-parasympathetic interactions on heart rate through release of neuropeptide Y (NPY) and its action on prejunctional NPY Y2 receptors on vagal and sympathetic nerve fibers. In other studies on various preparations and in various organs, attenuation of transmitter release has in fact been demonstrated through activation of the NPY Y2 receptor. In the present study on anesthetized dogs we examine, however, for the first time if vagal bradycardia is attenuated by endogenous NPY released during intense cardiac sympathetic stimulation. In addition, we explore if sympathetic transmitter release and heart rate, during moderate sympathetic stimulation, are affected through this receptor system. The significance of the NPY Y2 receptor was revealed by performing experiments before and after administration of its specific receptor antagonist BIIE0246. We found that attenuation of the bradycardia during vagal nerve stimulation was dose-dependently counteracted by BIIE0246 and that the tachycardia elicited by sympathetic stimulation remained unaffected after NPY Y2 receptor blockade. Thus, endogenous NPY appears to attenuate vagal bradycardia by stimulating prejunctional NPY Y2 receptors on cardiac vagal nerve terminals and, less efficiently, to attenuate transmitter release and tachycardia through a feedback loop on the cardiac sympathetic nerve fibers.